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AP Psychology
Research Methods Review
Research Design!
Types of Research Design

Correlational
The variables are only measured
 Some relationships can only be investigated using
correlational designs due to practicality or ethical concerns
 Cannot imply causality
 Examples include: Naturalistic Observation, Surveys, Case
Studies, and Archival Analysis


Experimental
The independent variable is manipulated in the experiment
 Subjects/Participants are randomly assigned to conditions



Experimental Group (receives manipulation)
Control Group (no manipulation)
Experimental or Correlational?

Experimental – you must be able to MANIPULATE the independent variable within
ethical and practical boundaries.

Experiment consists of comparing 2 or more groups, at least one of which receives the
manipulation and one standard control.



Use statistics that compare the groups on the outcome variable



Assignment to either group is RANDOM
You can manipulate more than one variable/dimension if you want!
T-test
ANOVA
Correlational – you only measure the two (or more) variables in question
Participants are measured on these domains either all at once or over time
(longitudinally)
 Uses statistics that measure the direction, intensity, and strength of the relationship
between variables



Correlation = relationship -1<r<1
Regression = predictive a + bx = y
Experimental Variables

Independent Variable: variable that is
manipulated by the experimenter.

Dependent Variable: variable that is
measured – the outcome variable.

The variables must have clear operational
definitions



How do you define aggression? Intelligence?
Operational Definitions help researchers REPLICATE
experiments
Increases RELIABILITY
Casual Relationships

Causal Relationships:

Causal relationships can only be determined in
controlled experiments

Requirements to imply causation:

The cause (independent variable) must precede the
effect (dependent variable) in time

The cause and effect covarry (they have a predictable
relationship)

The relationship between the variables cannot be
explained by another third or confounding variable
Three Core Requirements for
Research

Reliability
◦

Validity
◦

The consistency of data resulting from psychological testing or
experimental research
The information produced by the research accurately reflects the
variables that were intended to manipulate or measure
Standardization
◦
a set of uniform procedures for treating each participant in a test,
interview, or experiment.
◦
Standard Operating Procedures (SOP’s) need to be followed to
ensure each participant/client is treated the same
◦
If standardization is not followed, confounding variables may
influence and invalidate the results.
Reliability

Test-retest Reliability


If you test the same person a second time, do they get the same
score?
Internal Consistency

The degree to which items on a test are correlated with each
other



Some items should be positively correlated, some negatively correlated
If you split the test into two equal parts, do you get the same
result for each part?
Inter-rater Reliability

Do multiple raters score the same # of behaviors?
Operational Definition
 Boxing (Pacquiao v. Bradley)

Validity (of the experiment)


Internal Validity

Is the effect due to the experimental manipulation?

Within the experiment and those participants involved, can the effect be
said to ONLY be the result of the Independent Variable
External Validity


Population External Validity

Can the effect be generalized to individuals not involved in the
experiment?

What similarities might be important for the population to share with
the original participants in order for the effect to be the same?
Ecological Validity

To what extent does the experiment translate “in the wild”?
Validity: Efficacy vs.
Effectiveness vs. Efficiency

Efficacy: under controlled circumstances, does the
intervention produced the desired effect?

Effectiveness: under real-world circumstances, does the
intervention produced the desired effect?

Efficiency: is the treatment worth it’s cost to the
individual or society?
Validity (of measures)

Face Validity


Does it look like it measures what it’s supposed to?
Content Validity

Does the test cover all aspects of the construct?


Concurrent Validity


An IQ test that only tests math is not a valid IQ test
Does the measure correlate with other known measures of the same construct?
Predictive Validity

How well does the measure predict other measures of the same construct over
time?

An IQ test should predict future intellectual success
Standardization

Standardization: a set of uniform procedures for
treating each participant in a test, interview, or
experiment.

Standard Operating Procedures (SOP’s) need to be
followed to ensure each participant/client is treated the
same

If standardization is not followed, confounding variables
may influence and invalidate the results.
Threats to Experimental Integrity

Threats to Internal Validity

Mortality

Regression toward the mean

Selection

Maturation

Instrumentation

Testing

History

Compensatory rivalry/Resentful demoralization

Experimenter Bias
Threats to Experimental
Integrity

Threats to External Validity

Placebo Effect

Situational Constraints

Sample Homogeneity


Artificiality
Demand Characteristics

The “good” participant

The “bad” participant

The “faithful” participant

The “apprehensive” participant
Random Stuff

Random Sampling
Having access to the entire population and
randomly picking individuals from that population
 Allows for generalization of results to the entire
population
 If the sample is large enough, it should be
representative of the entire population


Random Assignment
Randomly assigning the sample of subjects into
experimental/control conditions
 Ensures the groups are roughly the same at the
begining

Blind & Double-Blind


Blind Design: Participants do not know what condition they are in

“Farce” or “sham” treatments are used

Reduces demand characteristics
Double-Blind Design: Neither the participants nor the research
assistants (who have contact with the participants) know which
condition the participant is in.

Eliminates the self-fulfilling prophecy

Sometimes not feasible
Quasi-Experimental

Quasi-Experimental Designs

Similar to a traditional experiment, but without
random assignment of participants to the
experimental/control groups

The independent variable is still manipulated, but the
groups were purposefully chosen by the experimenter


Vulnerable to confounding variables
Practical or ethical restrictions prohibit the use of a
“true experiment”

Education / at risk youth

Drug Trials
Quantitative or Qualitative?

Quantitative:
Numerical in nature
 Lends easily to statistical
analysis
 Feels more “science-y”


Qualitative:
Observations that cannot easily
be given a numerical value
 Creates a narrative/story
 Provides insight into the
research question, generates
hypotheses


For future quantitative research
Uncovers trends
 Typically can only be done with
a few participants

Psychological Research
Methods

Between-Subjects design

Separate groups of people are assigned different treatments


Within-Subjects Design

The same people experience the different treatments and are re-tested


Control Group vs. Experimental Group
Before vs. After
Matched-Pairs Design

Pairs of subjects (or parts of subjects) are separated and given different
treatments

Twin Studies
Change over Time?



Longitudinal

Investigates the same individuals over time

Vulnerable to a variety of threats to internal validity

Can imply developmental trajectories

Can be long (obviously) and expensive
Cross-Sectional

Investigates different cohorts of individuals varying in age

Cohort Effects

Cannot directly imply developmental trajectory

Generally more practical, time- and cost-effective
Sequential

Mixes elements of Longitudinal & Cross-Sectional Designs

Has benefits and vulnerabilities of both
Ethics!
Research with living things


Humans = Participants
Animals = Subjects

Human research is governed at the university level by the
Institutional Review Board (IRB)

Animal research is governed at the university level by the
Institutional Animal Care and Use Committee (IACUC)
 Animal research is also governed by various federal
entities (USDA, FDA, NSF)
Principles of Research with Human
Participants
“Psychologists strive to benefit those with whom they
work and take care to do no harm…Psychologists
respect the dignity and worth of all people, and the
rights of individuals to privacy, confidentiality, and
self-determination.” (Ethical Principles of
Psychologists and Code of Conduct, APA)
Principles of Research with Human
Participants

Risk/Benefit analysis: comparison of the potential benefit (both to the
individual and the population) and the risk of harm to the participant

Only if the benefit outweighs the risk can a study be considered ethical

The allowable risk associated for a study investigating a cure for
cancer is higher than a study looking at productivity in the
workplace

If more than ‘minimal risk’ is involved in a study, increased scrutiny
is placed on the investigator to justify their method
Principles of Research with Human
Participants
•
Informed consent: the participant must be aware of what they
will be doing, what risk may be involved, and their rights as a
participant.
▫
The participant must be 18 years or older and be able to give
consent.

▫
Informed Assent is given to minors or special populations, along
with the consent of their legal guardian
Some level of deception is required in most studies, but that’s OK
Principles of Research with Human
Participants

Freedom to withdrawal at any time



Without penalty
Confidentiality

All participant information must be kept confidential

Exceptions: Harm to self, Harm to others, Neglect,
Potential victimization
Debriefing and protection from harm

Since most experiments require from deception at the
beginning, participants must be told the true purpose of
the study after they have completed the experiment
Principles of Research with Animal
Subjects
•
Risk/Benefit analysis is also carried out with animal subjects – but
researchers aren’t as concerned about the benefit to the individual
animal
•
Ethical research with animals strives to:
▫
Reduce: use as few animals as possible to get the desired information
▫
Replace: replace sentient animal models with alternatives, such as tissue
analysis and computer models
▫
Refine: the use of methods to minimize pain, suffering, and distress. Also
includes the use of enrichment to enhance animal welfare
Principles of Research with Animal
Subjects

Issues arise with the degree to which
information from animal models can be
generalized to humans.


However, many studies could ONLY be
ethically conducted with animals

Prenatal Studies

Drug Trials
Basic physiological and behavioral
processes are indistinguishable across
species
Statistics!
Statistics Supplement

Descriptive Statistics: Only focus on describing the
participants which have been observed


Measures of central tendency

Mean

Median

Mode
Variability

Range

Standard Deviation
Statistics Supplement

Inferential statistics

Determine whether a sample of data is due to
chance responding or due to a meaningful trend
 Can
compare two or more groups
 Can
compare a group to a known norm
 Can
compare longitudinal data from the same
group
The Normal Distribution
Statistics Supplement
Statistics Supplement

Many things are normally distributed:

Intelligence Scores

[(Mental Age) / (Chronological Age)] x 100 = IQ

Mean IQ = 100

Std. dev = 15

IQ over 130 is exceptionally smart

IQ under 70 is one criteria for Intellectual Disability
The Normal Distribution

Z-scores are used to find out where a person stands in reference to
the population

Percentiles: uses the normal distribution and the z-score to identify
where a particular score is compared with the population.

If someone is at the 50th percentile, they are exactly in the middle

If someone is at the 30th percentile, they have 30% below them and 70%
above them

If someone is at the 90th percentile, they have scored above 90% of the
population
Statistics Supplement

SAT v. ACT



SAT

Mean = 1026

SD = 209
ACT

Mean = 20.8

SD = 4.8
Which is better, getting a 1277 on the SAT or a 28 on the
ACT?
Common Statistical Tests

T-test
Used when comparing 1 group mean to a known [population] value
 Used when comparing 2 group means against each other


One-way ANOVA


Used when comparing the means 3 or more groups than vary on 1 dimension
Two-way ANOVA
Used when comparing the means of groups that vary on 2 dimensions simultaneously
 Used to investigate the interaction between two factors


Chi-Square Test


Used when comparing the categorical outcomes between two or more groups
Correlation, Pearson’s R

Used to look at the relationship between two numerical variables
Significant Results(?)

Null Hypothesis Significance Testing (NHST)
H0: There is no effect of the treatment
 Ha: There is an effect of the treatment

Assumes that the null hypothesis is true
Given this assumption the sample distribution would have predictable
characteristics
NHST tests to see how unlikely it would be to obtain a particular sample,
given this assumed distribution





An extreme score would represent a statistically unlikely event
Typically, p-values less than .05 indicate a significant
difference between groups

A more stringent or relaxed level of significance may be appropriate
Significant Results(?)

Null Hypothesis Significance Testing will tell you how
improbable getting a particular sample is, under the
assumption that there are no differences between groups

NHST does not tell you the Effect Size, or whether or not
these differences actually translate into something
meaningful

NHST is sensitive to large sample sizes – the larger the sample size the
more likely it is to detect a difference (Power)

However these differences may not translate into something meaningful.
Power

Power is the ability of a given study or statistical test to detect a relationship that
exists in the population.


i.e. the ability to correctly reject the null hypothesis
Power is influenced by a variety of factors:

Sample size (bigger n = more power)

Actual Effect Size (effect size in the population)

Reliability and Validity of measures


You want measures that are accurate and precise
Using a between subjects or a within-subjects design
Statistics Supplement

Statistical Significance
 Statistical
Significance is achieved when the probability of
getting a specific set of data by chance is extremely slim

Typically, this probability is less than .05 or 5%

IF the groups were the same, THEN the probability of getting that
sample by chance would be very unlikely. Therefore, the researcher
concludes that the groups are (probably) not the same.

Because of the way statistics tests work, a researcher can never
“prove” anything. They can only demonstrate how probable or
improbable a certain event is.

If someone claims they have “proven” anything, don’t trust
them.
Statistics Supplement


Type I Error: False Positive

The researcher incorrectly determines that there is an
effect when in reality none exists

The probability of a Type I error is α

α is determined by the researcher based on how bad
implications for a false positive would be
Type II Error: False Negative

The researcher incorrectly determines that there is not
effect when in reality there is an effect

The probability of a Type II error is β

β can be reduced by increasing Power
Statistics Supplement

Correlation & Regression

Correlation Coefficient R describes the strength and direction of the
relationship between two observed variables

-1≤ r ≤ 1


-1 being a perfect negative correlation

+1 being a perfect positive correlation

0 represents no relationship
Linear Regression equations draw an imaginary line through the data cluster;
the slope and intercept of the line is used to predict future values based on
previous data

Expressed as y = mx + b
Statistics Supplement
Correlation & Regression
Graphs!

Graphs are an excellent way to convey a lot of information efficiently



Bar graphs summarizing group means or proportions

Separate bars for each group

Used for comparing groups in an Experiment
Scatter plots

Dots for each case/individual with 2 measures (x, y)

Used for Correlational Designs
Line graphs demonstrating longitudinal performance

Separate lines for each group, connecting dots at each time point

For Longitudinal Designs